WO2001040817A1 - Dry load test apparatus - Google Patents

Abstract

A dry load test apparatus (40) has resistor main bodies (57R, 57S, and 57T) for high-voltage load test constituted by flat resistor assemblies (Ri, Si, and Ti), respectively, each of which comprises a number of long resistor elements (rj) planarly arranged parallel with spaces between them and connected in series at their ends to form strings of resistor elements in such a way that the corresponding resistor elements (rj) of the resistor assemblies (Ri, Si, and Ti) are connected to each other. The resistor assemblies (Ri, Si, and Ti) are respectively stacked to form the resistor main bodies with spaces between them in such a way that the flat faces of the resistor assemblies are parallel. The dry load test apparatus (40) is also provided with first switching members (SWaij and Swbij) one end of each of which is connected to an end of the corresponding resistor element (rj) and which form rows (SWai and SWbi) of the switching members, and inter-assembly conductive members (Cai and Cbi) which interconnect the other ends of the first switching members (SWaij and Swbij) of the rows (SWai and SWbi), and a vacuum circuit-breaker (high-voltage switch) (86) that connects some of the inter-assembly conductive members (Cai and Cbi) to a power source (three-phase AC generator (88)) under test.

Description

 Specification

 Dry load test equipment

 The present invention relates to a dry load test apparatus used for an electric load test of, for example, an AC generator and other power supplies.

Background art

 <Necessity of load test for private generator>

 In recent years, for facilities (buildings) that require power, such as factories, department stores, computer buildings, medical institutions, and commercial buildings, it is desirable that power be supplied stably even during a power outage. . Therefore, in facilities that require such power, a private generator such as a three-phase AC generator is installed, and when the power goes out, the private generator is operated urgently to supply power to the facility As a result, power is supplied stably even during a power outage.

 Such private power generators are not always operated and operated, but are limited to emergency power failures, and in that case, it is required that they operate reliably. For this reason, it is necessary to carry out a load test regularly so that the private generator can operate normally in the event of an emergency power failure.

As a method of load test of this private generator, the private generator is actually operated to generate electric power, and equipment that actually uses electric power in factories or department stores (such as indoor lighting and coolers). The best is to supply the generated electric power to an electric device. However, the load test takes a long time, and more than a dozen times of generator power-on / off tests and rapid power Since there is also a capacity up test, it is difficult to perform a load test using equipment that actually requires electric power (for example, electrical equipment such as indoor lighting and a cooler), which is not suitable for the test.

 Therefore, the actual situation is that the load test of a private generator is actually performed using a load test resistance device with a load resistor having a capacity commensurate with the capacity of the generator. .

Conventional load test equipment>

 A three-phase AC generator is used as a private generator as described above. For this reason, in the dry load test apparatus disclosed in Japanese Patent Application Laid-Open No. Hei 6-334725 and Japanese Patent Application Laid-Open No. Hei 7-433436, the R-phase, S-phase, Three star-connected fixed resistor units are used so that a load corresponding to the T phase can be obtained.

 In addition, each of the fixed resistance units has a resistance assembly including a plurality of rod-shaped resistance elements, and sets the load capacitance by a combination of the plurality of resistance elements.

 It should be noted that, besides the device disclosed in this publication, there is a device which can be set to switch the load capacity for a load test. For example, there are those disclosed in JP-A-9-15307, JP-A-9-15308, JP-A-9-15309, and the like. In the devices disclosed in these publications, a large number of resistance assemblies composed of a plurality of rod-shaped resistance elements are prepared, and the large number of resistance assemblies are arranged in a plurality of stages in a vertical direction. A resistance circuit for a load is formed from the resistance assembly. The resistance value of the load resistance circuit is changed by the switching combination of the multi-stage resistance assembly.

Also, a switch for selecting the resistance value of the load resistance for the load test as described above. A load test resistance device provided with a switching selection means is disclosed, for example, in Japanese Patent Application Laid-Open No. 2000-192 (P20000-1923A). There are others.

 <Load test equipment for mobile three-phase AC generators>

 The resistance devices for load testing of three-phase AC generators include a permanent type that is permanently installed in factories, devs, pumping stations, and hospitals, and a load resistance test that is installed in vehicles. There are transportation types that are transported to a facility that requires a load test only when they are used. For example, as a load test device of this mobile type, as shown in Fig. 5 OA (see Japanese Patent Application Laid-Open No. 9-153307), a dry load is placed on the bed 2 of the truck 1. Some have test equipment 3.

 The dry load test apparatus 3 includes a frame 4 mounted on a carrier 2 and a resistance unit for R, S, and T phases mounted adjacent to the frame 4. 5, 6, and 7. These resistance units 5, 6, 7 have the same configuration.

 As shown in FIG. 50B, each of the resistance units 5, 6, 7 is connected to a base frame 10 disposed on the frame 4 and between the frame 4 and the base frame 10. The mounted anti-vibration rubber 11, frame 4, base frame 10, anti-vibration rubber 11, fixed bolt 12, and fixed nut 1 screwed to both ends of fixed bolt 12 3 and 14.

The resistance units 5, 6, and 7 are arranged below the base frame 10 and the frame 4, and furthermore, the electric fan 15 mounted on the frame 4 and the base frame 1, 0 The insulator (insulating member) 16 fixed on the top, the housing 17 fixed on the insulator 16 and the upper and lower ends open, and the cooling air from the electric fan 15 are guided to the housing 17 It has a hood 18. As shown in FIG. 51, the housing 17 has a hexahedral shape formed from angles. The side opening of the arm 18 is closed with insulating plates 19a, 19b, 19c, and 19d.

 Further, each of the resistor units 5, 6, 7 has a resistor body 20R, 20S, 20T disposed in the nozzle 17. The resistor bodies 20 R, 20 S, 20 T have resistor assemblies R ,, S., T i [i = 1, 2, 3,... Η] arranged vertically in multiple stages. As shown in FIG. 51, the resistance assemblies R 1, S i, and T i are a plurality of rod-shaped resistance elements (heaters) 21 arranged side by side on a plane and having both ends held by insulating plates. And a conductive connecting piece 22 connecting a plurality of resistance elements 21 in series.

 Moreover, as shown in FIGS. 52 and 53, the resistance assemblies R i, S, and T i of the resistance units 5, 6, and 7 are individual vacuum circuit breakers (VCBs) that are high-voltage switches. It is connected to the main vacuum circuit breaker (main VCB) MB, which is a high-voltage switch, via B i [i = 1, 2, 3, ··· η].

 In this way, the multi-stage resistor assemblies R i, S i, and T i can be turned on and off by individual vacuum circuit breakers (individual VCBs) B, so that the fineness of the three-phase AC generator can be improved. It is possible to carry out a load test.

 That is, in such a configuration, the procedure for performing the load resistance input test of the three-phase AC generator 23 is as follows.

First, start the operation of the three-phase AC generator 23, and then turn on the main vacuum circuit breaker MB. Next, several of the individual vacuum circuit breakers (individual VCBs),, are turned on. In this case, for example, the load on the power generation capacity of the three-phase alternator 23 is 25% for the first 10 minutes, 50% for the next 10 minutes, 75% for the next 10 minutes, and 75% for the last. Operate a large number of individual vacuum circuit breakers (individual VCBs) Bi every 10 minutes so that 100% of the 10 minutes is 100%. In this way, the power generation capacity of the three-phase By taking data from the load test of the three-phase AC generator 23 while changing the load ratio, it is possible to perform a detailed load input test of the three-phase AC generator. I can do it.

 However, expensive vacuum circuit breakers (V CB) require resistor assemblies R ,,

Since it is provided for each S i, T i [i = l, 2, 3, ··· η], the cost of the dry load test equipment will increase significantly. In addition, taking into consideration the withstand voltage as well as securing the potential between the electrodes, the vacuum circuit breaker (VCB) と and the resistance assemblies R !, S,, T, [i = 1, 2, 3, ··· η] When connecting to and using a cable, the connection distance between the connecting cable and the vacuum circuit breaker (VCB) Β must be at least 10 centimeters. Therefore, as a result, the resistance device itself must be extremely large.

 Therefore, the present invention provides a dry-type load test apparatus that is compact and can set the resistance value of a load resistance for a load resistance test precisely, and can reduce the manufacturing cost of the apparatus. It is intended to do so.

Disclosure of the invention

In order to achieve this object, a dry load test apparatus according to the first aspect of the present invention is a flat load test apparatus comprising a plurality of elongated resistive elements which are arranged side by side at intervals and connected in series at ends. By providing a large number of resistor assemblies and arranging the multiple resistor assemblies in multiple stages at intervals so that the flat surfaces are parallel to each other, it is possible to cope with the resistance elements of the multiple stage resistor assemblies. A multi-stage resistor body for a high voltage load test provided with a number of resistor element rows each including a plurality of resistor elements, and a switching member row having one end connected to one end of each of the resistor elements in the resistor element row. A plurality of first switching members, A plurality of inter-assembly conductive members for connecting the other ends of the first switching member array of the first switching member array to each other; and a power supply under test for some of the plurality of inter-assembly conductive members. It is characterized by having one high-voltage switch connected to the switch.

 The invention according to claim 2 is the device according to claim 1, wherein the at least one end of the first switching member is connected to each end of the resistance element of the resistance element row. The feature is that it constitutes a series of switching members.

 Further, the invention of claim 3 is the invention according to claim 1, wherein one end of the first switching member is connected to each end of the resistance element of each of the resistance element rows, The present invention is characterized in that a switching member row corresponding to the above is configured.

 According to a fourth aspect of the present invention, in the first aspect, a short-circuit means for selectively short-circuiting the plurality of inter-assembly conductive members is provided. The invention according to claim 5 is characterized in that, in claim 4, the short-circuit means is a second switching member.

 According to a sixth aspect of the present invention, in the fifth aspect, the switching member includes a first and a second fixed contact intermittently connecting a set of a plurality of fixed contact pairs and the first and second fixed contacts of each of the fixed contact pairs. A plurality of movable contacts to be driven, and a driving means for driving the movable contact forward and backward with respect to the first and second fixed contacts of each of the fixed contact pairs to simultaneously switch the first and second fixed contacts of each of the fixed contact pairs. In addition to the above, the plurality of first fixed contacts and the plurality of second fixed contacts are connected to each other.

The invention of claim 7 is characterized in that, in claim 6, the driving means is a solenoid operated and controlled by an operation panel and a control circuit. The invention according to claim 8 is the invention according to claim 7, wherein the solenoid includes a coil and an actuator driven by a magnetic force of the coil, and the solenoid includes the movable contact and a driving direction thereof. It is characterized by being arranged on substantially the same straight line as.

 The invention of claim 9 is characterized in that, in claim 6, the driving means is an air cylinder whose operation is controlled by an air control circuit.

 In this invention, the dry load test device means a dry electric load test device. In other words, the dry load test apparatus does not cool the resistance element as a heat generating load with water, but cools it with dry air. Hereinafter, dry load test equipment is used in this sense. BRIEF DESCRIPTION OF THE FIGURES

Figure 1

 FIG. 1A is a plan view of a track on which the dry load test apparatus according to the present invention is mounted, and FIG. 1B is a side view of FIG. 1A.

Figure 2

 FIG. 2 is a schematic plan view schematically showing an internal dry load test apparatus in a cross section of the box for storing the apparatus shown in FIGS. 1A and 1B.

Fig. 3

 FIG. 3 is a schematic side view of the dry load test apparatus of FIG. 2 viewed from the direction of arrow A. Fig. 4

 FIG. 3 is a schematic side view of the dry load test apparatus of FIG. 2 viewed from the direction of arrow B. Fig 5

FIG. 5 is a schematic explanatory diagram showing an example of the dry load test apparatus and the power supply under test of FIGS. 1 to 4. Fig. 6

 FIG. 4 is an enlarged partial perspective view of a part of FIG.

Fig. 7

 Fig. 7A is a side view of the resistance unit shown in Figs. 3 and 4 with a part of the electric fan cut away, and Fig. 7B is an explanatory diagram of the insulating plate of Fig. 7A.

Fig. 8

 FIG. 7B is an enlarged cross-sectional view showing the relationship between the resistance unit and the switching member of FIG. 7A.

Fig. 9

 FIG. 9A is an explanatory view showing a part of the resistance element shown in FIG. 8 in a cutaway and detailed view, FIG. 9B is an explanatory view showing an enlarged end structure of the resistance element in FIG. 9A, and FIG. FIG. 9B is an explanatory view showing another example of the end holding structure of the resistance element in FIG. 9A. Fig. 10

 FIG. 9 is a circuit diagram of the dry load test apparatus of FIGS. 1 to 8.

Fig. 1 1

 FIG. 10 is a partially enlarged explanatory view of FIG. 10;

Fig. 1 2

 FIG. 3 is an explanatory diagram showing an arrangement relationship between a switching member and an inter-assembly conductive member as viewed from the direction of arrow A in FIG.

Fig. 13

 FIG. 3 is an explanatory diagram showing an arrangement relationship between a switching member and an inter-assembly conductive member as viewed from the direction of arrow B in FIG.

Fig. 14

FIG. 10 is an explanatory diagram showing a relationship between the resistance assembly of FIG. 10 and a member for short-circuiting a resistance element of the resistance assembly. Fig. 15

 FIG. 15 is a partially enlarged explanatory view showing the relationship between the resistance assembly and the switching member of FIG. 14.

Fig. 16

 FIG. 16 is a front view of the switching member shown in FIG.

Fig. 17

 FIG. 17 is a bottom view of the switching member of FIG. 16.

Fig. 18

 FIG. 17 is a longitudinal sectional view of the switching member of FIG. 16.

Fig. 19

 FIG. 9 is a diagram illustrating the operation of the switching member of FIG. 18.

Fig. 20

 FIG. 17 is a plan view of a contact holding case of the switching member of FIG. 16.

Fig. 2 1

 FIG. 18 is a left side view of the solenoid shown in FIG.

Fig. 2 2

 FIG. 2 is a plan view of FIG. 21.

Fig. 2 3

 FIG. 17 is a schematic circuit diagram for controlling the operation of the switching member shown in FIG. 16.

Fig. 24

 FIG. 6 is a control circuit diagram of the switching member shown in FIG. .

Fig. 25

FIG. 5 is a schematic explanatory view showing a connection example of resistance elements of the resistance assembly shown in FIG. 14. Fig. 26

 FIG. 26 is a partially enlarged explanatory view of FIG. 25.

Fig. 27

 FIG. 26 is an explanatory diagram of the resistance value of the resistor assembly by the connection of FIG. 25.

Fig. 28

 FIG. 15 is a schematic explanatory view showing another connection example of the resistance element of the resistance assembly shown in FIG. 14.

Fig. 2 9

 FIG. 28 is a partially enlarged explanatory view of FIG. 28.

Fig. 30

 FIG. 28 is an explanatory view of the resistance value of the resistor assembly by the connection of FIG. 28.

Fig. 3 1

 FIG. 15 is a schematic explanatory view showing still another connection example of the resistance elements of the resistance assembly shown in FIG. 14.

Fig. 3 2

 FIG. 3 is a partially enlarged explanatory view of FIG. 31.

Fig. 3 3

 FIG. 3 is an explanatory view of the resistance value of the resistor assembly by the connection of FIG. 31.

Fig. 3 4

 FIG. 16 is an explanatory diagram showing another example of the control circuit of the switching member shown in FIG. 15.

Fig. 3 5

 FIG. 4 is a schematic circuit diagram of a dry load test device according to a second embodiment of the present invention.

Fig. 36 FIG. 35 is a partially enlarged explanatory view of FIG. 34.

Fig. 3 7

 FIG. 6 is a control circuit diagram of the switching member of FIG. 35.

Fig. 3 8

 FIG. 36 is an explanatory diagram showing another example of a control circuit diagram of the switching member of FIG. 35. Fig. 3 9

 FIG. 16 is a plan view showing another example of the switching member shown in FIGS. 16 to 18.

Fig. 40

 FIG. 39 is a bottom view of FIG.

Fig. 4 1

 FIG. 16 is a plan view showing still another example of the switching member shown in FIGS. 16 to 18.

Fig. 4 2

 FIG. 4 is an air control circuit diagram of the switching member of FIG. 41.

Fig. 4 3

 It is explanatory drawing of another dry load test apparatus.

Fig. 4 4

 FIG. 4 is a right side view of FIG.

Fig. 4 5

 Fig. 45A is a side view of a part of the dry load test apparatus according to the fourth embodiment of the present invention, with a part broken away, and Fig. 45B is a modified example of Fig. 45A with a part broken away. FIG.

Fig. 4 6

FIG. 45 is a right side view of the dry load test apparatus of FIG. Fig. 4 7

 FIG. 46 is a plan view of FIG. 46.

Fig. 4 8

 FIG. 48A is an explanatory diagram schematically showing a connection example of the resistor unit of the present invention, and FIG. 48B is an explanatory diagram showing a connection state of the resistor unit of FIG. 48A. Fig. 4 9

 FIG. 4 is a plan view showing another example of the track on which the dry load test device according to the present invention is mounted.

Fig. 50

 FIG. 5 is a side view of a track on which a conventional dry load test device is mounted, and FIG. 5 is a side view of a resistance unit showing a part of an electric fan of FIG.

Fig. 5 1

 FIG. 55 is an explanatory view of the resistor assembly of FIG. 50.

Fig. 5 2

 FIG. 60 is an explanatory diagram showing a connection example of the resistor assembly of FIG. 50.

Fig. 5 3

 FIG. 57 is a circuit diagram of the resistor assembly of FIG. 52.

BEST MODE FOR CARRYING OUT THE INVENTION

 Embodiment i of the present invention

 Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 (a) is a plan view of a mobile dry load test apparatus according to the present invention, that is, a mobile electric load test apparatus, and FIG. 1 (b) is a side view of FIG. 1 (a).

 [Constitution]

This mobile dry load tester is composed of a track 30 and a dry load tester (electronic Air load test device) 40. The truck 30 has a carrier 31 and a box 32 provided on the carrier 31. In this box 32, a luggage compartment 33 is provided. Then, a dry load test apparatus 40 is provided in the cargo room 32.

Schematic configuration of the dry load test equipment 40>

 As shown in FIGS. 1 (b), 2, 3, and 4, the dry load test apparatus 40 includes a frame 41 provided in a cargo room 32 and a frame 41. It has resistor units 42, 43, and 44 for the R, S, and T phases that are adjacently arranged on the front and back (see Fig. 1 (a), Fig. 5, and Fig. 6). These resistor units 42, 43, and 44 have almost the same configuration.

<Each resistance unit 42, 43, 44>

 As shown in FIG. 7 (a), each of the resistor units 42, 43, and 44 includes a base frame 45 arranged on the frame 41, a frame 41 and the base frame 4 as shown in FIG. 5 Anti-vibration insulating rubber 46 with heat resistance and heat insulation interposed between them, and plates 47, 47 fixed to the upper and lower ends of the anti-vibration insulating rubber 46, and plates 47, 47 The fixed bolts 48, 48 are provided integrally with the fixed bolt 47 and penetrate the frame 41 and the base frame 45, respectively, and are screwed to both ends of the fixed bolts 48, 48, respectively. It has fixed nuts 49, 49.

Further, each of the resistance units 42, 43, and 44 is disposed below the base frame 45 and the frame 41, and is connected to the electric fan 5 attached to the frame 41. 0, an insulator (insulating member) 51 fixed on the base frame 45, a housing 52 fixed on the insulator 51 and having upper and lower ends open (see FIG. 6), and an electric fan 50 It has an insulating hood 53 that guides cooling air from the housing to the housing 52. As shown in FIG. 8, the nozzle 52 has a hexahedral frame 54 formed from an angle formed with an epoxy-based heat-resistant material. The insulating plates 55a, 55b, 55c, 55d, etc., made of slabs, are closed with side openings. The insulating plates 55a, 55, 55c (see Fig. 6) and 55d are fixed to the frame 54 with fixtures 56 such as port nuts. The side opening / closing plates of the insulating plates 55b, 55d, etc. can be replaced with side opening / closing plates of a heat-resistant and non-combustible material other than the insulating material. As this material, for example, an aluminum plate or an iron plate can be used.

As shown in FIG. 7 (b), a large number of mounting hole rows Hi [i = 1, 2, 3,... They are formed at equal pitch. The mounting hole array Hi is formed from a large number of mounting holes hi [j = 1, 2, 3,... In this embodiment, the mounting hole rows H ヽ are provided in 22 rows (i = n = 2 2), and the mounting holes h, 16 are provided in 16 rows (j = m = 16). The number of mounting holes hj is not limited to 16 and the number of mounting holes H is not limited to 22 rows. Incidentally, the mounting hole h ₅ of the upper and lower mounting holes column H i are provided alternately with shifted half a pitch to the left and right.

<Resistor body of each resistance unit 42, 43, 44>

Further, as shown in FIG. 2, FIG. 5, and FIG. 7 (a), each of the resistor units 42, 43, and 44 has a resistor body 57 R, 5 disposed inside the nosing 52. 7 S, 57 T. This resistor body 57 R, 57 S, 57 T is composed of a number of flat resistor assemblies R i, ST i [i = 1 , 2, 3 ··· !!] (see Fig. 10 and Fig. 11). In this embodiment, since there are 22 rows of mounting holes H 2, the resistance assemblies R i, S., T i are also provided in 22 stages corresponding to the mounting hole rows H i. FIG. 11 shows the overall connection relationship of the resistor assemblies RS i, and only large symbols are given for convenience of illustration. Further, since the configurations of the resistance assemblies R i, S i, and T i in FIG. 10 are the same, the common parts of the resistance assemblies R i, S Τ; Numerals that cannot be added in FIG. 10 due to the relationship shown in FIG. 10 will be described with reference to FIG.

As shown in FIG. 8, the resistance assemblies R i, S i, are arranged in a flat (planar) shape and have a plurality of rod-shaped resistance elements (heaters) r _s [insulators] at both ends. j = 1, 2, 3 · '· πι] and conductive connecting pieces 58 ai, 58 bi -i [j = which connect a plurality of adjacent resistance elements (heaters) ri in series at the ends. 1, 2, 3 · · · πιΖ 2]. Since the plurality of resistive elements (heaters) _rj are arranged corresponding to the mounting holes hi, in the present embodiment, there are ₁₆ corresponding to the mounting holes h. As described above, since the mounting holes hi of the upper and lower mounting hole rows H i are provided to be shifted by half a pitch to the left and right, the resistance elements mounted in the mounting holes hi of the upper and lower mounting hole rows H, ri are shifted by half a pitch to the left and right, and the resistive elements rj in the vertical direction are arranged in a zigzag. As a result, the cooling air supplied between the insulating plates 55a, 55b and 55c from below by the electric fan 50 is taken into the mounting holes hi of the upper and lower mounting hole rows Hi. This effectively hits the attached resistance element r _s and efficiently cools all the resistance elements ri in the mounting hole array Hi.

Note that multi-stage resistor assemblies R t R n each conductive connecting piece 5 8 a of, constitutes the connection piece column in a line vertically, multistage resistor assemblies R, each conductive connection piece to R _n 5 8 b i-, constitute a connection row in one row up and down, and each resistance element (heater) ri of the multi-stage resistor assembly R i to R _n is arranged in a row in the vertical direction to form a resistor row. ing.

 (Resistor element of resistance assembly R i, S T i)

As shown in FIG. 9A, the resistance element includes a cylindrical body 59 made of a metal material having high thermal conductivity or stainless steel, and a heat radiation fixed to the outer periphery of the cylindrical body 59. One end is inserted concentrically into both ends of the fin 60 and the body 59 Rod-shaped electrodes 61, 61, and insulators (insulating members) 62, 62, which are integrally and concentrically fixed to the outer periphery of the intermediate portion between the rod-shaped electrodes 61, 61. The insulator 62 is made of a ceramic insulator or the like, and has an annular groove 62a formed on its peripheral surface to prevent dust from adhering.

 The resistance element ri includes a resistance wire (a heater wire such as a chrome wire) 63 arranged at the center of the cylinder 59 and having both ends connected to the rod-shaped electrodes 61, 61; The insulating material (insulating member) 64 such as magnesia filled between the inner surface of the rod 59 and one end of the rod-shaped electrodes 61, 61 and the resistance wire 63 is connected to the other end of the rod-shaped electrode 61. It has screwed fixed nuts 65 and 65a.

 Then, the conductive connecting piece 58 is fixed to the resistance element ri by tightening between the fixing nuts 65 and 65a.

 Further, as shown in FIGS. 9A and 9B, an annular or cylindrical heat-resistant caulking material (heat-resistant sealing material) 64 a is fitted between the end of the cylindrical body 59 and the rod-shaped electrode 61. Then, the insulator (insulating member) 62 is used to hold the insulator 64, so that the heat-resistant caulking material 64a prevents moisture from entering the insulator 64. In order to withstand a high voltage, the length of the insulator 62 is set to, for example, about 10 mm or more, and the conductive connecting piece 58 and the cylindrical body 59 are connected to each other. The insulation distance between them is sufficiently ensured.

 An insulating member 66 having heat resistance and elasticity is fixed near both ends of the cylindrical body 59. The insulating member 66 is made of heat-resistant and elastic silicone rubber (synthetic resin) or the like. An annular mounting groove 66 a is formed in the center of the insulating member 66.

The resistance elements (heaters) _rj of the resistance assemblies R i, S i, and T i are arranged corresponding to the mounting holes hi of the mounting hole row Hi as described above. Then, the resistance element (heater) ri connects the insulating members 66, 66 at both ends to the insulating plates 55a, 55 5c mounting holes hi, hi fit into the insulation member 66, 66 6 annular mounting groove

By engaging the insulating plates 55a, 55c with 66a, 66a, they are fixed (held) to the insulating plates 55a, 55c.

 By holding the cylindrical body 59 on the insulating plates 55a and 55c with the insulating member 66 having heat resistance and elasticity having elasticity as described above, it is possible to prevent movement of the track. It is possible to prevent the vibration and shock from being transmitted to the resistance element ri, and to damage the resistance element ri due to vibration and shock. The insulating plates 55a and 55c supporting the resistance element ri are made of an epoxy resin-based relatively heat-resistant material, but the insulating member 66 is made of a heat-resistant silicone rubber. (Synthetic resin), etc., to prevent the heat of the resistance element r; from being directly transmitted to the insulating plates 55a, 55c, thereby making the insulating plates 55a, 55c durable. It improves the performance.

 Further, in the present embodiment, the insulating member 66 is formed from heat-resistant and elastic silicone rubber (synthetic resin) or the like, but is not necessarily limited to this. In other words, when the ^ -type load test device 40 is mounted on a truck and used without being moved, the insulating member 66 must be attached to the ceramic insulator 6 as shown in Fig. 9. Alternatively, the insulating members 6 6 ′ may hold the insulating plates 55 a, 55 c and the like.

Switching member>

As shown in FIGS. 1, 2, and 8, the dry load test apparatus 40 is connected to the resistance units 42, 43, and 44, and the resistance units 42, 43 are spaced apart from each other. It has insulating plates 67 and 68 located at positions sandwiching 43 and 44 (see Figs. 3, 4 and 6). These insulating plates 67, 68 extend in the direction of the arrangement of the resistance units 42, 43, 44, and cover the entire sides of the resistance units 42, 43, 44. It is formed in size. The lower ends of these insulating plates 67, 68 It is attached to the frame 41 by mounting means such as bolts and nuts (not shown).

 As shown in FIG. 2, the surfaces 67a and 68a of the insulating plates 67 and 68 on the side opposite to the resistance units 42, 43 and 44 are provided with the first [I = 1, 2, 3, · · · η] are arranged in multiple stages corresponding to the resistance assemblies R i, S i, and T i ( See Figure 3, Figure 4, Figure 12, Figure 13, and Figure 14).

Each of the first switching member rows SW a SW b, has half the number of the first switching members SW a of the resistance elements R i, S i, and T i of the resistance elements (heaters) ri. i, SW b ■ ₅ [j = 1, 2, 3, '' ππΖ2]. The first switching members SW _aii and SW b have normally open contacts and are attached to insulating plates 67 and 68, respectively.

 (Structure of switching member S W a ■ i, S W bu)

 The first switching members SWa and SWbii have a structure as shown in FIGS. 16 to 23. That is, the first switching members SWai and SWbu have the case 69. This case 69 consists of a contact case (split case) made of insulating material such as Teflon that can withstand high voltage and is separable from each other and that can withstand high voltage. It has a solenoid case made of insulating material (split case) 71. As shown in FIG. 20, the contact case 70 is provided with two sets of fixed contact pairs including first and second fixed contacts Pa and Pb. The fixed contacts P a and P a are arranged side by side on one side of the contact case 70, and the fixed contacts P b and P b are arranged side by side on the other side of the contact case 70.

In addition, a contact holding member 72 made of an insulating material such as a synthetic resin is provided between the fixed contacts Pa, Pa and the fixed contacts Pb, Pb at positions sandwiching the fixed contacts Pa, Pa. It is arranged so that it can move in parallel with the arrangement direction of Pa. The contact moving member 72 is spring-biased by a spring 73 to one side in the longitudinal direction (to the left in FIGS. 18 to 20).

 As shown in FIGS. 18 and 19, the contact holding members 72 are provided with contact moving slits 72 a and 72 a that penetrate left and right at intervals in the longitudinal direction. On one of the end walls of the contact moving slits 72a, 72a, projections 72b, 72b for holding the spring are formed. One ends of the springs 74, 74 are fitted and held in the protrusions 72b, 72b, and the other ends of the springs 74, 74 have plate-like movable contacts M, M, respectively. The projections 75 and 75 provided at the center are fitted and held. The springs 74, 74 press the movable contacts M, M against the end walls of the contact-moving slits 72a, 72a.

 The contact portions at both ends of the movable contact M are oriented to the fixed contacts Pa and Pb. In addition, the contact portions at both ends of the movable contact plate M are separated from the fixed contacts Pa and Pb by the panel force of the spring 73, and the contacts Pa and Pb are normally open contacts. The fixed contacts Pa and Pa are connected by a terminal plate 76, and the fixed contacts Pb and Pb are connected by a terminal plate 77. With this configuration, the contacts Pa, Pa, Pb, and Pb can withstand a certain high voltage.

 Inside the opening of the solenoid case 71, there is provided a base plate 78a that can withstand a high voltage such as Teflon, and this base plate 78a is connected to the space inside the case 71. The space and in case 72 are insulated against high voltage. A solenoid holding frame 78 fixed to the base plate 78a is fixed in the solenoid case 71, and a solenoid S is fixed to the solenoid holding frame 78. Installed as a driving means.

The solenoid S is fixed to the solenoid holding frame 78 and holds the contact. An iron core 79 extending parallel to the member 72, a coil (solenoid body) 80 wound around the iron core 79, and a solenoid holding the iron core 79 so as to be able to move forward and backward with respect to the iron core 79. It has a movable iron plate 81 held by a frame 78 and an insulating engagement plate 81a formed of a material capable of withstanding high voltage, such as Teflon, and fixed to the movable iron plate 81. The insulating engaging plate 81a protrudes further downward from the movable iron plate 81, and the tip (lower end) of the insulating engaging plate 81a engages with the engaging recess 72b of the contact holding member 72. ing. An energization control circuit 84 is connected to the coil 80 via lead wires 82 and 83.

 These lead wires 82 and 83 are drawn out from the solenoid case 71 at the edge away from the contact case 70. As a result, the lead wires 82 and 83 are set so as to be separated from the fixed contacts Pa and Pb and the movable contact M. The withstand voltage between the lead wires 82 and 83 is improved.

 When the coil 80 is energized by the energization control circuit 84, the movable iron plate 81 is attracted and moved to the fixed iron core 79 by magnetic force, and is magnetically attached to the fixed iron core 79, and The solenoid S is activated (ON). In addition, the insulating engagement plate 81a, which moves together with the movable iron plate 81 by this suction movement, causes the contact-holding member 72 to move against the panel force of the spring 73 in FIGS. Move to the right. As a result, the movable contact M is brought into contact (contact) with the fixed contacts Pa and Pb, and the fixed contacts Pa and Pb are made conductive (short-circuited).

(Connection to sweep rate Tsuchingu member SW a. _5, SW bu conductive connecting piece)

One end (fixed contact P a) of the first switching member SW a is connected to the conductive connection piece 58 ai, respectively, and one end (fixed contact P a) of the first switching member SW bi is connected to the first switching member SW bi. ) it is. electrically conductive connection pieces of the resistor elements _{gamma iota} is attached One end (fixed contact P a) of the remaining first switching member SW b is connected to the conductive connecting piece 58 b i-, respectively.

Conducting member between assembly

 In addition, the other end (fixed contact Pb) of the first switching member SW ai of the multiple resistor assemblies S i and T i arranged in multiple stages vertically is connected to the inter-assembly conductive member C ai [ j = l, 2, 3 '' '^ 2], and are electrically connected to each other. Similarly, the other end (fixed contact P b) of the first switching member SW b, of a number of resistor assemblies RS>,>, which are arranged in multiple stages vertically, is connected to the inter-assembly conductive member C bi [ j = l, 2, 3, · · · · πιΖ 2], and are electrically connected to each other. Further, the resistance element r of many resistance assemblies R i, S i, and T i has an end E to which no conductive connection piece is attached, and a conductive member between assemblies.

It is connected to C b (»/ 2) _{+ 1} and conducts with each other.

 <Connection of resistor assembly Ri, Si, Ti>

 The connection relationship between the resistance assemblies R i, S i, and T i is as shown in FIG. Since FIG. 14 illustrates the resistance assemblies R i, S i, T, at the same time, in FIG. 14, for convenience of illustration, the reference numerals are attached with the minimum necessary, and the detailed description is shown in FIG. This is explained in 15 below. In FIGS. 14 and 15, illustration of the insulating plates 67 and 68 shown in FIG. 8 is omitted for convenience of explanation.

The inter-assembly conductive member Cb / _{2) +1} of the resistor assembly R is connected to the contact 86 R of the main vacuum circuit breaker (VCB) 86 via the wiring 85 R. , resistor assembly S assembly between conductive members of _{i C b (10/2)} + 1 wiring 8 5 via the S main vacuum circuit breaker is a high-voltage sweep rate pitch (VCB) 8 6 contacts 8 6 S, is connected to the resistor assembly T assembly between the conductive member C b / ₂ of _{i) + 1} is main Lee down of the vacuum circuit breaker via a line 8 5 T (VCB) 8 6 contacts 8 6 T, connected to You. The contacts 86 R ₂ , 86 S ₂ , and 86 T ₂ of the vacuum circuit breaker (VCB) 86 are connected to the three-phase AC generator 88 via wiring 87 R, 87 S, 87 mm. Connected to the R, S, T phase contacts 88 R, 88 S, 88 Τ.

 As described above, by providing the switching members SWa, SWb and the inter-assembly conducting members C a C bj, C b ^ / + i, conventionally, each of the resistor assemblies RS,, Τ, The structure that was turned on and off by the vacuum circuit breaker (VCB) for each stage is no longer required, and the vacuum circuit breaker (VCB) requires only one main vacuum circuit breaker (VCB) 86.

Load switching connection member>

 The dry load test apparatus 40 has short-circuit means for short-circuiting some resistance elements ri of the resistance assemblies R i, S,, T. The short-circuit means include short-circuit connecting wires 89, 89, short-circuit connecting wires 90, 90, 90, conductive plates (conductive connecting members) 91, 91, 91 and Prepare conductive plates (conductive connecting members) 92, 92, and 92 that are connected to each other.

<Electrification control circuit 8 4>

 As shown in FIG. 24, the energization control circuit 84 includes a low-voltage switch 93 for a low-voltage load test, a high-voltage switch 94 for a high-voltage load test, and a high-voltage load test, as shown in FIG. And a power supply 96 is connected via a power supply switch 97. The electric fan 50 is driven and controlled by an energization control circuit 84.

[Action]

 Next, the operation of the dry load test apparatus 40 having such a configuration will be described.

In such a configuration, the track 30 moves the dry load test apparatus 40 to the site where the load test is performed. In the present embodiment, the location where the three-phase AC generator 88 is installed as the electrical equipment to be subjected to the voltage load test Become.

 As described above, the resistor bodies 57 R, 57 S, and 57 T provided in each of the resistor units 42, 43, and 44 of the present embodiment are flattened in two stages. It has a resistance assembly R ,, ST. In addition, 16 rod-shaped resistance elements r, of the resistance assemblies R i, S i, Τ, are provided.

 In addition, eight switching members SWau and SWbii of the above-described switching member rows SWa! And SWb are provided. Therefore, the coil 80, which is the solenoid body of the switching member SWa, is made to correspond to S :! to S8 in FIG. 24, and the software of the switching member SW bii is set. An example of a voltage load test is described below, in which the coil 80, which is the main body of the lens, is associated with S9 to S16.

 Further, in this embodiment, since the three-phase AC generator 88 is used as an electric device to be subjected to the voltage load test, the three-phase AC generator 88 is connected to the resistance of the dry load test device 40. The case of connection to the main body 57R, 57S, 57T as shown in Fig. 5 is explained.

 (1) Low voltage load test

For example, when a low voltage load test of 400 V is performed, first, as shown in FIGS. 25 and 26, the conductive members Cb to Cb ( _m C) Conduct (short-circuit) ₊₁ with the conductive plate 91 and conduct (short-circuit) the conductive member C b! Cb ^ / +! Between the assembly of the resistor body 57 S with the conductive plate 91, Conductive member between the assembly of the anti-main body 5 丁: じ ( _m / _{2) + 1} is conducted (short-circuited) by the conductive plate 91.

As a result, the R, S, and T phases of the three-phase AC generator 88 have conductive switches 58 b] to 58 b all of the switching member rows SW b and SW b _n. Assembly of the chin member SW bij and the resistance body 57 R, 57 S, 57 T Cb! / Cb ^ / + !, conductive plate 91 ', wiring 85R, 85S, 85T and vacuum circuit breaker 86 via resistor assembly R ,, S ,,, The resistance element ri of T, is connected.

On the other hand, the resistance body 5 7 R of the assembly between the conductive member _{C a, ~ C a m /} 2 is made conductive (short-circuited) with the conductive plate 9 2, resistor body 5 7 assembly between ¾ conductive member S C _ai ~ C a _m / 2 conduction conductive plate 9 2 (short) is, causes conduction resistance body 5 7 assembly between the conductive member C a ₂ for T in the conductive plate 9 2-circuited. As a result, the resistance elements r of the resistance assemblies R i and ST i constituting the resistance bodies 57 R, 57 S and 57 T are connected to the conductive connection pieces 58 a! _(m / _2), between the assembly conductive members _{C ai - C a m / 2} , sweep rate Tsuchingu member column SW a, the voltage across all sweep rate Tutsi ring member SW a and the conductive plate 9 2 ~ SW a _n 0 Connected to each other at neutral point.

In this state, as shown in FIG. 27, the sixteen resistance elements ri of the resistance assemblies R i, S i,, are all connected in parallel. Moreover, in the R, S, and T phases of the three-phase AC generator ₈₈ , all the resistance elements _ri are connected in parallel to reduce the resistance value of the load assembly R i, S., T i ( That is, the resistor element bodies 57 R, 57 S, and 57 T) having a low resistance value are connected.

 In such a connection, the three-phase AC generator 88 is operated, while the power switch 97 is turned ON to operate the energization control circuit 84. Thereafter, the low-pressure switch 93 is turned ON. By this ON operation, the energization control circuit 84 first turns on the main vacuum circuit breaker 86, and then turns the coil 80 (S 1) of the switching members SW a .i and SW bu. To S16) to turn on all of the switching members SW aii and SW bii.

As a result, the output (voltage, current) from the three-phase AC generator ₈₈ is input to the resistance elements _ri of the resistance assemblies R i, S i, and T i, and the load test is started. You. As a result, current flows through the resistance elements of the resistance assemblies R i, S i, Τ, and the resistance element ri generates heat.

 At this time, the energization control circuit 84 activates the electric fans 50 of the resistance units 42, 43, and 44 to remove the cooling air from the electric fans 50 to the resistance unit. Vent to the housing 52 of the sockets 42, 43, and 44. The cooling air absorbs the heat generated by the resistance elements ri of the resistance units 42, 43, and 44 when flowing around the heat radiating fins 60, and removes the resistance elements ri. After cooling, the air is exhausted to the outside from an exhaust port (not shown) of the box 32 forming the cargo room 33.

Even in this case, by controlling the OΝ and OFF of the switching members SW _aii and SW bii in each stage, the resistance main body 57 R, 57 S, 57 T power, the three-phase AC generator, etc. The load test is performed by changing the load resistance value applied to 8 to 25%, 50%, 75%, 100% at predetermined time intervals, for example. Further, in the present embodiment, since there are provided two stages of flat resistor assemblies R i, S i, T, the ratio of the load resistance value applied to the three-phase AC generator 88 is set more finely. You can. For example, a load test can be performed every 5% and 10%. (2) 3 3 0 0.V high voltage load test

If for example, 3 3 0 0 cormorants row high voltage load test of V, first, the cormorants I shown in FIG. 2 8, the assembly between the conductive members C b ₅ resistive body 5 7 R resistor body 5 7 S connect the conductive member C b ₅ between the assembly in the connection line 8 9 is short-circuited, the assembly between the conductive members C b ₅ of the assembly between the conductive members C b ₅ resistive body 5 7 S resistor body 5 7 T Connect with connection line 8 9 to short-circuit. In addition, the conductive members C bi and C b ( _m / _{2) +1} between the assembly of the resistor bodies 57 R, 57 S, and 57 T are connected by connecting lines 90, 90, 90, respectively. Short-circuit (see Fig. 29).

In this state, as shown in FIG. 30, each resistor assembly R i, ST i Each of the 16 resistive elements ri is connected in parallel with two resistors 8 r, 8 r each having a value in which half of the eight resistive elements ri are connected in parallel. Are connected to a neutral point where the voltage becomes 0 via a switching member SW bi ₅ and connection lines 89, 89.

 Also, the R, S, and T phases of the three-phase AC generator 88 have resistor bodies 57 R, 5

Conductive member between each assembly of 7S, 57T CbCb _(m / _{2) + 1} is wiring 90, 90, 90, wiring 851, 85S, 85T and vacuum Connected via circuit breaker 86.

 Therefore, the R, S, and T phases of the three-phase alternator 88 have a resistance assembly R i, S having resistors 8 r, 8 r connected in parallel and having a medium resistance value. Τ, (that is, the medium resistance resistors 57 R, 57 S, 57 T) are connected.

In such a connection, the three-phase AC generator 88 is operated, while the power switch 97 is turned on to operate the energization control circuit 84. After this, turn on the high voltage switch 94. By this ON operation, the energization control circuit 84 first turns on the main vacuum circuit breaker 86, and then switches the members SW b ■:, SW bis coils 80 (S 1, S 1 by energizing the 5), causing oN the sweep rate pitch ring member SW bi SW b _{i S.} As a result, the output (voltage, current) from the three-phase alternator 88 is input to the resistor assemblies R, S i, and T i, and the load test is performed. Be started. As a result, the resistor

Electric current is applied to each of the resistance elements ri constituting 8r and 8r, and the resistance elements ri generate heat.

At this time, the energization control circuit 84 activates the electric fans 50 of the resistance units 42, 43, and 44, and cools the cooling air from the electric fans 50 to the resistance unit. G to the housing 52 of 42,43,44. And this cooling The wind absorbs heat generated in the resistance elements Γ of the resistance units 42, 43, and 44 when flowing around the heat radiating fins 60, cools the resistance element ri, and then cools down the cargo room. Air is exhausted to the outside from an exhaust port (not shown) of the box 32 that forms 33.

Even in this case, by controlling the OΝ and OFF of the switching members SW _aii and SW bu of each stage, the resistor body 57 R, 57 S, 57 T power, and the three-phase AC generator can be used. 8 8 The load test is performed by changing the load resistance value applied at 8 to 25%, 50%, 75%, and 100% at predetermined time intervals. Further, in the present embodiment, since there are provided two stages of flat resistance assemblies R i, S i, and T i, the ratio of the load resistance value applied to the three-phase AC generator 88 is set more finely. You can. For example, a load test can be performed every 5% and 10%.

(3) 660 V high voltage load test

 For example, when performing a high voltage load test of 660 V, as shown in FIG. 31, the conductive members C b between the assembly of each of the resistor bodies 57 R, 57 S, and 57 T are used. Connect C b C b, respectively, with connection lines 89, 89, 89 to short-circuit

(See Figure 32). This ensures that each resistor assemblies R i, S., Each resistor element Rrir ₁₆ is Sui etching member T, SW b _iie, through _{SW b il 6, SW b.} 16及Pi connection lines 8 9, 8 9 Are connected to a neutral point where the voltage becomes zero.

In addition, the R, S, and T phases of the three-phase AC generator 88 are connected to the conductive members C b _(m / _{2) +1} between the assembly of the resistor bodies 57 R, 57 S, and 57 T. They are connected via 90, 90, 90, wiring 85 R, 85 S, 85 T and vacuum circuit breaker 86.

In this state, as shown in FIG. 33, each of the resistor assemblies R i, S i, and T i is formed by connecting all the resistor elements ri of the 16 resistor elements rj in series, and Becomes high resistance.

 Therefore, the R, S, and T phases of the three-phase alternator 88 have a resistance assembly R i, S., T. (Ie, high resistance) having all resistance elements r, connected in series. The value of the resistor body (57R, 57S, 57T) is connected.

 In such a connection, the three-phase AC generator 88 is operated, while the power switch 97 is turned ON to operate the energization control circuit 84. Thereafter, the high pressure switch 95 is turned ON. By this ON operation, the energization control circuit 84 first turns on the main vacuum circuit breaker 86, and then energizes the coil 80 (S1) of the switching member SW b H, Turn on the switching member SW b H. As a result, the output (voltage, current) from the three-phase AC generator 88 is supplied to the resistance elements ri of the resistance assemblies Ri, Si, and Ti, and the resistance element ri generates heat. .

 At this time, the energization control circuit 84 activates the electric fans 50 of the resistance units 42, 43, and 44, and the cooling air from the electric fans 50 is cooled by the resistance fans. Ventilate the housing 52 of the units 42, 43, and 44. This cooling air absorbs the heat generated by the resistance elements r! Of the resistance units 42, 43, and 44 when flowing around the heat radiating fins 60, and the resistance element r! After being cooled, the air is exhausted to the outside from an exhaust port (not shown) of the box 32 forming the load chamber 33.

In this case as well, by controlling the OΝ and OFF of the switching members SW _aii and SW bii in each stage, the resistance main body 57 R, 57 S, 57 T power, the three-phase AC generator, etc. The load test is performed by changing the load resistance value applied to 8 at predetermined time intervals, for example, to 25%, 50%, 75%, and 100%. Further, in this embodiment, since there are provided two stages of the flat resistor assemblies R i, S., T, the ratio of the load resistance value applied to the three-phase AC generator 88 is set more finely. This You can also. For example, a load test can be performed for each of 5% and 10%. In such a load test, the low-voltage switch 93 for the low-voltage load test, the high-voltage switch 94 for the high-voltage load test, and the high-voltage switch 95 for the high-voltage load test were turned on. In this case, the current is automatically controlled by the energization control circuit 84 in accordance with a load test program. This program can be stored in advance in a storage means such as a ROM (not shown) of the power supply control circuit 84, or can be stored in a recording medium such as a hard disk. Alternatively, the load control circuit 84 can read and use the CPU (not shown) at the start of the load test.

 (Modified example)

 In the embodiment described above, when the low-voltage switch 93 for the low-voltage load test, the high-voltage switch 94 for the high-voltage load test, and the high-voltage switch 95 for the high-voltage load test are turned on, However, the load test is performed according to the program, but the present invention is not limited to this. For example, as shown in FIG. 34, the coil 80 of the switching member SWa indicated by S1 to S8 and the coil 8 of the switching member SW bii indicated by S9 to S16. Switch SW 1 to SW 16 for ON / OFF operation of the switching members SW aii and SW b of each stage are provided corresponding to 0, and S 1 to SW 16 are provided by switches SW 1 to SW 16. It is also possible to control the energization of the coil 80 shown in S16. In addition, the vacuum circuit breaker 86 can also be operated by the switch 98 to perform the ON / OFF operation.

 (Other)

In the embodiment described above, the conductive connection pieces 58 a, to 58 a 58 a! To 58 a (»/ ₂ ) of the resistance assembly R i, S i, Τ Switching members SW a and SW b are connected to all of the It is not limited to this. For example, in the present embodiment, Sui tool quenching _{member, + C b C b C b} , Ru can also (m = 1 6 thus C b ₉₎ Nino viewed provided the structures child.

 Embodiment 2 of the present invention

[Constitution]

In the first embodiment of the present invention, before conducting the low-voltage load test, the 330-V voltage load test, and the 660-high voltage load test, the connection lines 89, 90 and the conductive plates 9 An example was shown in which some of the resistance elements _ri of the resistance assemblies R, S,, were manually connected (short-circuited) in advance using 1, 92, etc., but this is not necessarily required. It is not limited.

For example, as shown in Fig. 35, three conductive plates (short-circuit means) 92 connected in series by connecting wires (short-circuit means) 99, 99 are provided, and each conductive plate 92 is connected to the resistor body. 5 7 R, 5 7 S, 5 7 T assembly between the conductive member C a, the second Sui etching member SW _{C j} is a short-circuit device [; j = l, 2, 3 · · · πιΖ 2] a while connected through the three conductive plates 9 1 resistance body 5 7 R, 5 7 S, 5 7 second sweep rate Tsuchingu member an assembly between the conductive member C bi shorted means T SW d ₅ [j = 1, 2, 3 · · · (m / 2) + 1] (see Figure 36 for details). The second switching members SW ci and SW di as the short-circuit means have the same configuration as the first switching members SW ai and SW d as the short-circuit means (the configurations in FIGS. 16 to 23). Can be used. Moreover, a row of first switching members SWa, SWd is provided for each of the resistor assemblies R, Si, T, and is multistage. Therefore, the second switching members SWci, SWd; need only be able to short-circuit the inter-assembly conductive members C a and the inter-assembly conductive members C bi, so that only one row is required. In addition, the conductive members CbCbCb between the assembly of the resistor bodies 57R, 57S, and 57T are electrically connected to each other by a vacuum circuit breaker (VCB) 100, which is a high-voltage switch. Short-circuit) Connect as much as possible, and connect the conductive members CbCbCb between the assembly of the resistor bodies 57R, 57S, and 57T with a vacuum circuit breaker (VCB) 101, which is a high-voltage switch. They are connected to each other so that they can conduct (short circuit), and the conductive members C bi, C bi, C and C b ( _m / _{2) +1} , C b between the assembly of the resistor bodies 57 R, 57 S, and 57 T connecting + i, Ji _{3/2) + 1} [in this embodiment, since is _{2 = 8 C b + 1 =} C b 9] and the vacuum circuit breaker is a high voltage sweep rate Tutsi (VCB) 1 0 2 .

 Also, if the coil 80 of the second switching member SW ci is SI 7 to S 24 and the coil 80 of the second switching member SW dj is S 24 to S 32, As shown in FIG. 37, the solenoids S17 to S32 are also operated and controlled by the power supply control circuit 8'4. The same parts as those in FIG. 24 are denoted by the same reference numerals as in FIG. 24, and description thereof will be omitted.

[Action]

 (1) Low voltage load test

 In such a connection, when performing a low-voltage load test of, for example, 400 V, first, while the three-phase AC generator 88 is operated, the power switch 97 is turned on and the energization control circuit is turned on. 8 Operate 4.

After this, turn on the low voltage switch 93. With this ON operation, the energization control circuit 84 turns on the main vacuum circuit breaker 86 first, and then turns on the resistance assemblies that constitute the resistor bodies 57 R, 57 S, and 57 T. By energizing all of the coils 80 (S 1 to S 8) of the switching members SW au of R i, S i, and T i, the switching members SW a are turned on, and the resistor bodies 57 R, 5 7 S, 57 T The switching member SW of the resistance assemblies R i, S i, T, which constitute T Energize all of the _C j coils 80 (SI 7 to S 24) and turn on all of the switching members SW ci.

As a result, the resistance elements 1 ″ of the resistance assemblies R,, S i, and D, which constitute the resistance bodies 57 R, 57 S, and 57 T, are connected to the conductive connection pieces 58 & ₁ to 5 8 & ₍₁ »/ ₂ ), all switching members SW ai to SW a, conductive members between assemblies C a. To C a Switching members SW c ₁ to SW _cm / ₂ and conductive plate 92 Connected to a neutral point where the voltage is zero.

 In addition, the electric control circuit 84 also switches the coil 80 (S 9 to S 9) of the switching member SW bii of the resistor assemblies R i, ST, which constitute the resistor bodies 57 R, 57 S, 57 T. 16) is turned on, all the switching members SW bii are turned ON, and the switching of the resistance assemblies R,, S>, which constitute the resistance main bodies 57 R, 57 S and 57 T, is performed. Energize all the coils 80 (S25 to S32) of the member SW di and turn on all of the switching member SW di.

As a result, the R, S, and T phases of the three-phase AC generator 88 have conductive connecting pieces 58 b, to 58 b, all of the switching member rows SW b SW bn of the switching member row. bii (SW bii SW bi im /), resistor body 57 R, 57 S, 57 T, inter-assembly conductive member C b ₁ to C b _(ro / _{2) + 1} , switching member SW c! , ~ SW d _{+ 1} and the conductive plate 91, the wirings 85 R, 85 S, 85 T and the vacuum circuit breaker 86, and the resistance elements ri of the resistance assemblies R i, S i, T, It is connected.

In this state, as shown in FIG. 27, the sixteen resistance elements ri of the resistance assemblies R i, S, are all connected in parallel. In addition, in the R, S, and T phases of the three-phase AC generator ₈₈ , all the resistance elements _ri are connected in parallel to _{reduce the} load resistance R, S i, T, (ie, Low resistance resistance book Bodies 57R, 57S, 57T) are connected. As a result, the output (voltage, current) from the three-phase AC generator 88 is input to the resistance elements of the resistance assemblies R, S i, T, and the load test is started. As a result, the resistance element _ri of the resistance assembly Ri, S i, T is energized, and the resistance element generates heat.

 At this time, the energization control circuit 84 activates the electric fans 50 of the resistance units 42, 43, and 44, and cools the cooling air from the electric fans 50 to the resistance unit. To the housings 52 of the sockets 42, 43 and 44. The cooling air absorbs the heat generated by the resistance elements r of the resistance units 42, 43, and 44 when flowing around the heat radiating fins 60, and the cooling air flows through the resistance elements. After cooling, the air is exhausted to the outside from an exhaust port (not shown) of the box 32 forming the cargo room 33.

 Even in this case, the ON / OFF control of the switching members SW ii and SW bu of each stage can be performed, so that the resistor body 57 R, 57 S, 57 T force, the three-phase AC generator 8 A load test is performed by changing the load resistance value applied to 8 at predetermined time intervals, for example, to 25%, 50%, 75%, and 100%. In the present embodiment, the flat resistance assemblies R 1, S 2, T 3! Since two stages are provided, the ratio of the load resistance value applied to the three-phase AC generator 88 can be set more finely. For example, a load test can be performed every 5% and 10%. (2) 330 V high voltage load test

 For example, when performing a high voltage load test of 330 V, the three-phase AC generator 88 is operated, while the power switch 97 is turned ON to operate the energization control circuit 84.

After that, turn on the high voltage switch 94. With this ON operation, the energization control circuit 84 first turns on the main vacuum circuit breaker 86 and the vacuum circuit breaker 101. After the N is applied, the coil 80 (S5) of the switching member SW bii of the resistance assembly Ri, Si, Τ constituting the resistor body 57R, 57S, 57T is energized. Turn on the switching member SW bi ₅ . Thus, the resistance elements _ri of the resistance assemblies R i, ST, which constitute the resistance main bodies 57 R, 57 S, 57 T, are formed by the conductive connection pieces 58 b ₅ , the switching members SW b _{i 5.} Connected to the neutral point where the voltage becomes 0 via the inter-assembly conductive member Cb and the vacuum circuit breaker 101.

That is, in this state, as shown in FIG. 30, each of the sixteen resistor elements rj of each of the resistor assemblies R i, S, and the half eight resistor elements _ri are connected in parallel. The two resistors 8 r, 8 r having the same values are connected in parallel, and one end of the parallel resistors 8 r, 8 r is a conductive connecting piece 58 b ₅ , a switching member SW b ₁₅ , an assembly voltage via the Mashirubeden member C b ₅ and the vacuum interrupter 1 0 1 are connected to each other in the neutral point becomes zero.

 In addition, along with this, the electronic control circuit 84 turns on the vacuum circuit breaker 102 and also sets the resistor assemblies R 1, S i, T i constituting the resistor main bodies 57 R, 57 S, 57 T. The coil 80 (S9) of the switching member SW bii is energized to turn on the switching member SW bu of each resistance assembly Ri, S.

This ensures that the three-phase AC generator 8 8 R, S, the T-phase, conductive connecting piece 5 8 ~ 8 b Control button quenching member column SW b! ~ SW b _n of Sui Tsu quenching member SW bi , Resistor body 57 R, 57 S, 57 T Inter-assembly conductive members C b!, C b (= C b ₉ ), vacuum circuit breaker 102, conductive plate 91, wiring 85 R , _{85 S, 85} T and the vacuum circuit breaker ₈₆ , the resistance elements of the resistance assemblies RS i, T, are connected.

As a result, the output (voltage and current) from the three-phase AC generator 88 is input to the resistors 8 r and 8 r of the resistor assemblies R i, S i and T i, and the load test is performed. start Is done. As a result, power is supplied to each of the resistance elements _ri forming the resistors _8r , _8r , and the resistance elements ri generate heat.

Even in this case, the ON / OFF control of the switching members SW _aii and SW bu of each stage can be performed to obtain the three-phase AC generator ₈₈ R from the resistor bodies ₅₇ R, 57 S and 57 T power. The load test is performed by changing the load resistance value applied to the load at predetermined intervals, for example, to 25%, 50%, 75%, and 100%. Further, in this embodiment, since there are provided two stages of flat resistance assemblies R !, S, and Ti, the ratio of the load resistance value applied to the three-phase AC generator 88 is set more finely. You can do that too. For example, a load test can be performed every 5% and 10%. (3) 660 V high voltage load test

 For example, when performing a high voltage load test of 660 V, the three-phase AC generator 88 is operated, while the power switch 97 is turned ON to activate the energization control circuit 84.

 Thereafter, the high pressure switch 95 is turned ON. By this ON operation, the energization control circuit 84 first turns on the main vacuum circuit breaker 86 and the vacuum circuit breaker 100, and then turns on the resistor bodies 57R, 57S, 57T. The coil 80 (S1) of the switching member SWb of the resistance assembly Ri, Si, Ti constituting the resistor assembly is energized to turn on the switching member $ Wb.

 Accordingly, the resistance elements r of the resistance assemblies R i, S i, and T i that constitute the resistance bodies 57 R, 57 S, and 57 T are connected to the conductive connection pieces 58 bi and the switching section. Material SW b Conductive member between assemblies. C bt and vacuum circuit breaker 100 0 are connected to each other to a neutral point where the voltage becomes zero.

The R, S, and T phases of the three-phase AC generator 88 are connected to the conductive members C b _(m / _{2) +1} between the assembly of the resistor bodies 57 R, 57 S, and 57 T. 90, 90, 90, connected via wiring 85R, 85S, 85T and vacuum circuit breaker 86 You.

 In this state, as shown in FIG. 33, each of the resistor assemblies R 1, ST ′ has a resistance value of 髙 resistance where all the resistance elements ri of the 16 resistance elements ri are connected in series. It becomes the state of having become.

 Therefore, in the R, S, and T phases of the three-phase AC generator 88, a resistance assembly R i, S i, T i (that is, a high resistance) in which all resistance elements Γ are connected in series is provided. The value of the resistor body (57R, 57S, 57T) will be connected.

 By the control operation of the energization control circuit 84 as described above, the output (voltage and current) from the three-phase AC generator 88 is applied to the resistance elements ri of the resistance assemblies R, S <, Τ, When energized, the resistance element ri generates heat.

At this time, the energization control circuit 84 activates the electric fans 50 of the resistor units 42, 43, and 44, and resists the cooling air from the electric fans 50. Ventilate the nozzles 52 of the nits 42, 43, and 44. This cooling air absorbs the heat generated by the resistance elements r _の of the resistance _{units 42} , _43, and ₄₄ when flowing around the heat radiating _{fins 60,} and _causes the resistance element _rj to be absorbed. After cooling, the air is exhausted to the outside from an exhaust port (not shown) of the box 32 forming the cargo room 33.

In this case as well, by controlling the OΝ and OFF of the switching members SW _aii and SW bii in each stage, the resistance main body 57 R, 57 S, 57 T power, the three-phase AC generator, etc. 8 8 The load test is performed by changing the load resistance value applied at 8 to 25%, 50%, 75%, and 100% at predetermined time intervals. Further, in the present embodiment, since there are provided two stages of flat resistance assemblies R i, S i, T, the ratio of the load resistance value applied to the three-phase AC generator 88 is set more finely. You can. For example, a load test can be performed every 5% and 10%. Such a load test is performed by using a low-voltage switch 93 for a low-voltage load test and a high-voltage switch. When the high-voltage switch 94 for the voltage load test and the high-voltage switch 95 for the high-voltage load test are turned on, the energization control circuit 84 automatically operates according to the program for the load test. It is being told. This program can be stored in advance in a storage means such as a ROM (not shown) of the power supply control circuit 84, or can be stored in a recording medium such as a hard disk. Also, at the start of the load inspection, the load can be read into a CPU (not shown) of the conduction control circuit 84 and used.

 In this way, the energization control circuit 84 only operates the low-voltage switch 93, the high-voltage switch 94, and the high-voltage switch 95 to turn on the resistor bodies 57R, 5R. Automatically sets the resistance value of the 7 S, 57 T resistor assembly R i, S., T i and performs the load test automatically. As a result, it is possible to switch the complicated switch easily, quickly and optimally (accurately). Also, according to the present embodiment, each of the resistor bodies 57 R, 57 S, 57 T constitutes a multi-stage (22 stage in this embodiment) resistor assembly R, S i, T i. It is not necessary to provide a vacuum circuit breaker at all, and there are only three vacuum circuit breakers, denoted by 100, 101, and 102, so even if automated, the equipment would be large in size. In addition, the cost hardly increases.

 (Modification 1)

Also in the second embodiment, when the low-voltage switch 93 for the low-voltage load test, the high-voltage switch 94 for the high-voltage load test, and the high-voltage switch 95 for the high-voltage load test are turned on. However, the load test is performed according to the program, but the present invention is not necessarily limited to this. For example, as shown in FIG. 38, the coil 80 of the switching member SWa shown by S1 to S8 and the coil 80 of the switching member SWb shown by S9 to S16 Correspondingly, ON / OFF operation of the switching members SW aii and SW b of each stage The switches SW1 to SW16 for operation are provided, and the switches SW1 to SW16 are used to control the energization of the coil 80 indicated by S1 to S16. You can do it. In addition, the vacuum circuit breakers 86, 100, 101, and 102 may be turned on and off with switches 98, 98a, 68b, and 98c. it can.

 (Modification 2)

Also, the vacuum circuit breaker 102 is not always necessary. That is, when the high voltage switch 94 is turned on, the energization control circuit 84 turns on the switching members SW dt and SW d < _ra / _{2) +1} (= SW d ₉ ), and the vacuum is shut off. Vessel 1

0 2 can be omitted. In this case, even if it is automated, the number of vacuum circuit breakers can be reduced by one as compared with the above-described embodiment, so that the cost can be further reduced and the size can be reduced.

 (Modification 3)

 In the first and second embodiments of the invention described above, the switching member S W a,

1, SW bii, switching member SW c 3 ¥ (1 mm etc. are provided with the solenoid 3 and the contact holding member 72 holding the movable contact M side by side, but it is not necessarily limited to this. Absent.

For example, as shown in FIG. 39, a solenoid node S having a movable iron plate (actuator) 81 driven by the magnetic force of the coil 80 and the coil 80 is provided, and a contact case is provided. 70 is provided with a solenoid mounting portion 70a, and a solenoid S is provided on the contact holding member 72 in substantially the same straight line as the driving direction of the movable contact M. It may be configured to be mounted on the node mounting part 70a (see Fig. 40). In this case, the distance between the fixed contacts PI and P2 and the coil 80 is set so as not to discharge. Also, the lead wires 82, 83 of the solenoid S are provided at the end remote from the fixed contacts P1, P2. As a result, Discharge prevention measures can be taken between the lead wires 82 and 83 and the fixed contacts PI and P2.

 In this case, the contact holding member 72 has a small hole 72c formed at the tip of the solenoid node S side, and the movable iron plate 81 is engaged with the small hole 72c. When the coil 80 is energized to generate a magnetic force in the iron core 79, the movable iron plate 81 is attracted to the iron core 79 by the magnetic force, and the contact holding member 72 is moved to the right in FIG. The movable contacts M, M turn on the fixed contacts Pa, Pa and Pb, Pb, as in the first embodiment of the invention. Also, as shown in the drawing, by providing a flange F at a portion between the case 70 of the contact holding member 72 and the solenoid S, the solenoid S and the contacts M, P a , Pb can be more reliably insulated. Further, by forming the contact holding member 72 from Teflon or the like, it becomes possible to withstand a higher voltage. This point can be applied to all of the above-described embodiments and the later-described embodiments.

 (Modification 4)

In the first and second embodiments of the invention described above, the switching members SW aii, SW b «j, the switching members SW _{C i} , SW di, etc., are of the magnet type using the solenoid S. The example used is shown, but it is not limited to this.

For example, the _switching members SW _aii and SW bii, and the switching members SW cj and SW di may be air-type switches as shown in FIG. 41.

In this modification, the air cylinder 200 is used as a driving means instead of the solenoid S of the switching members SW _aij and SW bii and the switching members SW ci and SW di. Provided.

The air cylinder 200 is connected to the cylinder body 200 as shown in FIG. 1, a piston 202 disposed in the cylinder body 201, and a piston rod 203 integral with the piston 202. The piston rod 203 is engaged with the contact holding member 72 in series. The cylinder body 201 has air chambers A and B defined by pistons 202, and ports 2 that open to the air chambers A and B, respectively. 0 1 a and 2 0 1 b are formed. This port 201b is open to the atmosphere. The operation of the air cylinder 200 is controlled by an air control circuit AC.

 The air control circuit AC has an air compressor 204, an air tank 205 and an electromagnetic valve 206. An air compressor 204 is connected to a port 201 a of the air cylinder 200 via an air tank 205 and an electromagnetic valve 206. An electromagnetic valve 208 and a pressure sensor 209 are connected to a pipe 207 connecting the port 209a and the port 201a. The solenoid valve 208 opens the air chamber A to the atmosphere when activated. The pressure detection signal from the pressure sensor 209 is input to the arithmetic and control circuit 210, and the air compressor 204 and the electromagnetic valves 206 and 208 are sent to the arithmetic and control circuit 210. The operation is controlled more. A pressure sensor 211 is connected to the air tank 205, and a pressure detection signal from the pressure sensor 211 is also input to the arithmetic and control circuit 210.

 In such a configuration, the arithmetic and control circuit 21 operates the air compressor 204 to store compressed air in the air tank 205. Accordingly, when the pressure from the pressure sensor 211 reaches a predetermined value, the operation of the air compressor 204 is stopped. .

The arithmetic and control circuit 210 controls the operation of the switches 94, 95, 96 and the like to operate and open the electromagnetic valve 206. This allows. Compressed air is guided from the air tank 205 to the air chamber A of the cylinder body 201 via the pipe 207. This compressed air moves the piston 202 to the right by staking the panel force of the spring 73 shown in Figs. 18 and 19 and moving the movable contact M to the fixed contacts Pl, P 2 and press contact. The arithmetic and control circuit 210 closes the electromagnetic valve 206 when the pressure detection signal from the pressure sensor 209 exceeds a predetermined value and the change in the pressure detection signal becomes constant. Let it. Incidentally, the arithmetic control circuit 2 1 0 Sui etching member SW aii, SW b. I, scan I Tsuchingu member SW ci, in use the load test SW d ₅ and the like, the pressure is a predetermined value from the pressure sensor 2 0 8 When the pressure becomes below, the electromagnetic valve 206 is opened and compressed air is supplied to the air chamber A again.

 When the load test is completed, the arithmetic control circuit 210 opens the solenoid valve 208 to open the air chamber A to the atmosphere. As a result, the contact holding member 72, the piston rod 203, and the piston 202 are displaced to the left in FIG. 42 by the panel force of the spring 73. Then, the air in the air chamber A is exhausted to the atmosphere via the electromagnetic valve 208, and the movable contact M is separated from the fixed contacts P1, P2.

Ri by such a Eashiri Sunda 2 0 0 sweep rate Tsuchingu member SW aij, SW bi _s, sweep rate Tsuchingu member SW cj, to the child as a driving means such as SW di used in place of the Soviet Union Leno I de S, Sui etching member SW a, SW b. i, sweep rate Tsuchingu member SW ci, it can use in a safe state Ri by the SW d ₅ and the like.

 [Embodiment 3]

In the embodiment described above, an example of the dry load test apparatus of the type used for the three-phase AC generator is shown, but the present invention is not necessarily limited to this. For example, using only one of the resistor assemblies R i, ST, of the resistor body 57 R, 57 S, and 57 T, is used for the power supply under test such as a generator or a battery. An electrical load test may be performed.

 [Embodiment 4]

 Also, separately provided resistor units 42, 43, 44 are connected in parallel, and each resistor unit 42, 43, 44 has a resistor body 57R, 57S, 5R. Although a 7 T resistor assembly R i, S i, and T i are provided, the configuration is not necessarily limited to this.

 For example, if the voltage of the power supply under test is relatively small even at a high voltage, the number of stages of the resistor assemblies R i, S i, Τ, and the number of stages should be reduced to, for example, two or three, and As shown in 43 and 44, separately provided resistor units 42, 43 and

4 4 may be assembled up and down to form one dry load test apparatus 300. In FIGS. 43 and 44, the number of stages of the resistance assemblies R i and S _{i (} Τ) is set to one for convenience of illustration, but actually two or three.

 In this case, the resistance units 42, 43, and 44 have metal box-shaped frames 301, 301, and 301, respectively. It is necessary to arrange an insulating member 302 between 3, 4 and 4, and to have a certain insulation distance between the frame 301 and the resistor assembly Ri, Si, Τ. is there. For this reason, the intervals between the resistor bodies 57 R, 57 S, and 57 T become large, and the height of the dry load test apparatus 300 tends to be high, which is not desirable.

 Therefore, as shown in Fig. 45A, Fig. 46 and Fig. 47, the resistor body 57 R,

A dry load test apparatus 400 incorporating only 57 S and 57 resistance assemblies 1 S i may be used. The dry load test apparatus 400 has a rectangular parallelepiped (box-like) metal (eg, iron) frame 401 having four side surfaces and two upper and lower surfaces opened, and a frame 4. It has insulating plates 402 to 405 that close the opening to the side of 01. Then, the resistor bodies 57 R, 5 The 7 S, 57 T resistor assembly R i, S., T, is fixed between bridge plates 402, 404.

 In this case, since there is only one frame 401, the distance between the resistor bodies 57R, 57S, 57mm can be made smaller than those in FIGS. As a result, the dry load test apparatus 400 can be much smaller in height than the dry load test apparatus 300. In this example as well, the number of stages of the resistor assemblies R., S i, and T i is set to one for convenience of illustration, but the number is actually two to three.

 In addition, the insulating plates 403 and 405 are removed from the side force of the frame 401, and the two opposing side surfaces located between the insulating plates 402 and 404 of the frame 401 are removed. The motorized fan 50 may be attached to one of the openings as shown in Fig. 45B, and the upper and lower openings of the frame 401 may be closed. . In this case, the cooling air from the electric fan 50 flows into the frame 401 from the opening on the side of the frame 401 as shown by the arrow 401a. After cooling the internal resistance element, it is exhausted from the opening on the other side. With this configuration, the height of the dry load test device 400 can be further reduced, so that the dry load test device 400 can be incorporated into a small truck. Also, depending on the installation location, it can be easily installed in places where height cannot be secured. The electric fan 50 is attached to the frame 41, and the cooling air generated from the electric fan 50 is indicated by an arrow 401a through the insulation hood 53. As described above, the fluid flows into the frame 401 from the opening force on the side surface of the frame 401.

 (Other 1)

In the above-described embodiment, an example is shown in which the R-phase resistance unit 42, the S-phase resistance unit 43, and the T-phase resistance unit 44 are provided one by one. It is not necessarily limited to this. For example, as shown in Figures 31 to 33 As described above, the resistance elements r, of the resistance units 42, 43, and 44 are connected in series for 660 V, and the resistance units 42, 43 connected in series with , 44 are provided as shown in Fig. 48A, and two sets of each resistor unit 42,

4 2 and 2 sets of each resistance unit 4 3 and 4 3 and 2 sets of each resistance unit 4 4 and 4

 ,

 The configuration in which 44 are connected in series as shown in Fig. 48B allows a load test of 13200 V to be performed. Note that this connection example is just an example. By increasing the number of resistor units 42, 43, and 44, the voltage at which a load test can be performed can be increased.

 (Other 2)

 In the first embodiment of the present invention described above, the dry load test apparatus 40 provided with the resistance units 42, 43, and 44 is mounted on the track 30 and the dry load test apparatus 40 is provided. After transporting the test equipment 40 to the site where the electric load test is to be performed by the track 30, perform the electric load test with the dry load test equipment 40 mounted on the track 30. However, this is not necessarily the case.

For example, as shown in Fig. 49, the resistor units 42, 43, and 44 corresponding to the R, S, and T phases are removably mounted on the truck 30 loading platform. Please keep it. Then, the resistance units 42, 43, and 44 are transported to the site where the electric load test is to be performed by the track 30, and the tracks 30 are then transferred from the track 30 to the site. Remove and remove from track 30. After that, the resistance units 42, 43, and 44 are installed on the site with the configuration as in the first embodiment of the invention, and the electric load test of the power source such as the generator at the site is started. . In FIG. 45 to FIG. 47, only one resistor assembly R i, S,, T i is shown for convenience of explanation, but actually, several are provided in multiple stages. Jikamo, 5 8 j of the first embodiment of the invention, C a _s, C bi like the resistance assembly R i, S i, as in the first embodiment of the invention the T i set However, in the present embodiment, the illustration is omitted for convenience of illustration. Therefore, since the track 30 does not need to be kept on site during the electric load test, the other resistance units 42, 43, and 44 are transported to another site, or the resistance of other sites is not used. It can be used to recover units 42, 43, and 44. As a result, the track 30 can be used effectively and effectively. The invention's effect

 As described above, the dry load test apparatus according to the first aspect of the invention is a tuft-shaped dry load test apparatus including a large number of elongated resistive elements that are flatly arranged at intervals and connected in series at the ends. By providing a large number of resistor assemblies and arranging the multiple resistor assemblies in parallel at intervals so that the M-plane becomes parallel, the resistance elements of the multi-stage resistor assembly are provided. A multi-stage high-voltage load test resistor body provided with a number of corresponding resistor element arrays, and one end connected to one end of each of the resistor elements in the resistor element array. A plurality of first switching members constituting a row of switching members, and a number of inter-assembly conductive members connecting the other end portions of the first switching member row of the switching member rows to each other And some of said multiple inter-assembly conductive members. With a single high-voltage switch that connects the power supply to the power supply under test. Can be made cheaper.

Further, the invention according to claim 2 is characterized in that one end of the first switching member is connected to each end of the resistance element of at least some of the resistance element rows, respectively. With this configuration, the number of parts can be minimized. The invention according to claim 3, wherein one end of the first switching member is connected to each end of the resistance elements of all the resistance element rows, and the switching member row corresponding to each of the resistance element rows is provided. Therefore, the resistance value of the resistor assembly can be set more finely by connecting (short-circuiting) a large number of conductive members between the assemblies.

 The invention of claim 4 is the invention according to claim 1, wherein a short-circuit means for selectively short-circuiting the plurality of inter-assembly conductive members is provided, so that a plurality of inter-assembly conductive members are connected. The resistance value of the resistor assembly can be set more finely depending on the method (short circuit).

 According to the invention of claim 5, in claim 4 ^, the short-circuit means is a second switching member, so that the ON / OFF operation of the first and second switching members enables A combination of resistor assemblies to be short-circuited can be selected easily and quickly.

 The invention according to claim 6 is the device according to claim 5, wherein the switching member interrupts the first and second fixed contacts with one set of a plurality of fixed contact pairs and the first and second fixed contacts of each of the fixed contact pairs. A plurality of movable contacts; and driving means for driving the movable contacts forward and backward with respect to the first and second fixed contacts of each of the fixed contact pairs to simultaneously connect and disconnect the first and second fixed contacts of each of the fixed contact pairs. At the same time, the plurality of first fixed contacts and the second fixed contacts are connected to each other, so that they can be used for high voltage with a simple structure.

 The invention according to claim 7 is the invention according to claim 6, wherein the driving means is a solenoid that is operated and controlled by an operation panel and a control circuit. The combination of assemblies can be selected easily and quickly and automatically.

The invention according to claim 8 is the method according to claim 7, wherein the solenoid is a coil and a coil. The actuator has an actuator driven by the magnetic force of the coil, and the solenoid is arranged on the same straight line as the movable contact and its driving direction. The withstand voltage between the two can be easily secured.

 According to a ninth aspect of the present invention, in the sixth aspect, the driving means is an air cylinder whose operation is controlled by an air control circuit, so that the withstand voltage with respect to the fixed contact and other parts can be easily secured. .

Claims

The scope of the claims

1. A plurality of flat-shaped resistor assemblies each including a plurality of elongated resistive elements which are arranged side by side at a flat interval and connected in series at an end portion, wherein the plurality of resistor assemblies are parallel to each other in a flat plane. The multi-stage high-voltage load provided with a large number of resistance element rows each composed of the corresponding ones of the resistance elements of the multi-stage resistive assembly is provided by arranging them in parallel at intervals so that A resistance body for testing,

 A plurality of first switching members each having one end connected to one end of each of the resistance elements of the resistance element row to form a switching member row; and a first switching member row of the switching member row. A number of inter-assembly conductive members for connecting the other ends of the

 A dry load test apparatus comprising a high voltage switch for connecting some of the plurality of inter-assembly conductive members to a power supply under test.

 2. One end of the first switching member is connected to each end of the resistance elements of at least some of the resistance element rows to form a switching member row. The dry load test device according to claim 1.

3. One end of each of the first switching members is connected to each end of the resistance elements of all the resistance element rows to form a switching member row corresponding to each of the resistance element rows. 2. The dry load test apparatus according to claim 1, wherein:

4. The dry load test apparatus according to claim 1, further comprising a short-circuit means for selectively short-circuiting the plurality of inter-assembly conductive members.

5. The dry load test apparatus according to claim 4, wherein the short-circuit means is a second switching member.

 6. The switching member according to claim 5, wherein the switching member comprises a first and a second fixed contact, and a plurality of fixed contact pairs and a plurality of movable contacts for interrupting the first and second fixed contacts of each of the fixed contact pairs. And a driving means for driving the movable contact to move forward and backward with respect to the first and second fixed contacts of each of the fixed contact pairs, thereby simultaneously intermittently connecting the first and second fixed contacts of each of the fixed contact pairs. A dry load test apparatus characterized in that a plurality of first fixed contacts and a plurality of second fixed contacts are connected to each other.

 7. The dry load test apparatus according to claim 6, wherein the drive means is a solenoid operated and controlled by an operation panel and a control circuit.

 8. In claim 7, the solenoid includes a coil and an actuator driven by a magnetic force of the coil, and the solenoid is substantially co-linear with the movable contact and a driving direction thereof. A dry-type load testing device characterized by being installed.

 9. The dry load test apparatus according to claim 6, wherein the driving means is an air cylinder whose operation is controlled by an air control circuit.